Structure, Function and Dynamics of G-Protein coupled Receptors

Understanding the function of membrane proteins is crucial to elucidate the molecular mechanisms by which transmembrane signaling based physiological processes,i. e., the interactions of extracellular ligands with membrane-bound receptors, are regulated. In this work, synthetic transmembrane segments derived from the visual photoreceptor rhodopsin, the full length system rhodopsin and mutants of opsin are used to study physical processes that underlie the function of this prototypical class-A G-protein coupled Receptor. The dependency of membrane protein hydration and protein-lipid interactions on side chain charge neutralization is addressed by fluorescence spectroscopy on synthetic transmembrane segments in detergent and lipidic environment constituting transmembrane segments of rhodopsin in the membrane. Results from spectroscopic studies allow us to construct a structural and thermodynamical model of coupled protonation of the conserved ERY motif in transmembrane helix 3 of rhodopsin and of helix restructuring in the micro-domain formed at the protein/lipid water phase boundary. Furthermore, synthesized peptides and full length systems were studied by time resolved FTIR-Fluorescence Cross Correlation Hydration Modulation, a technique specifically developed for the purpose of this study, to achieve a full prospect of time-resolved hydration effects on lipidic and proteinogenic groups, as well as their interactions. Multi-spectral experiments and time-dependent analyses based on 2D correlation where established to analyze large data sets obtained from time-resolved FTIR difference spectra and simultaneous static fluorescence recordings. The data reveal that lipids play a mediating role in transmitting hydration to the subsequent membrane protein response followed by water penetration into the receptor structure or into the sub-headgroup region in single membrane-spanning peptides carrying the conserved proton uptake site (monitored by the fluorescence emission of hydrophobic buried tryptophan). Our results support the assumption of the critical role of the lipid/water interface in membrane protein function and they prove in particular the important influence of electrostatics, i. e., side chain charges at the phase boundary, and hydration on that function.Für die Aufklärung der molekularen Wirkungsweise von physiologischen, auf Signaltransduktion, d. h. dem Zusammenspiel von extrazellulären Reizen und membrangebundenen Rezeptoren, beruhenden Prozessen ist das Verständnis der Funktion von Membranproteinen unerlässlich. In dieser Arbeit werden von Rhodopsin abgleitete, synthetische transmembrane Segmentpeptide, Opsin-Mutanten und der vollständige Photorezeptor Rhodopsin untersucht, um die physikalischen Prozesse zu beleuchten, die der Funktionen dieses prototypischen Klasse-A G-Protein gekoppelten Rezeptors zugrunde liegen. Die Abhängigkeit der Membranprotein-Hydratation und der Lipid-Protein-Wechselwirkung von der Ladung einer Aminosäuren-Seitenkette wird erforscht. Hierzu werden synthetische, transmembrane Segmentpeptide in Lipid und Detergenz, als Modell transmembraner Segmente von Rhodopsin in der Membran mittels Fluoreszenzspektroskopie untersucht. Aus den erhaltenen Ergebnissen wird ein thermodynamisches und strukturelles Modell hergeleitet, welches die Kopplung der Protonierung des hochkonservierten ERY-Motivs in Transmembranhelix 3 von Rhodopsin an die Restrukturierung der Helix in der Mikroumgebung der Lipid-Wasser-Phasengrenze erklärt. Des Weiteren werden sowohl die Segementpeptide als auch die vollständigen Systeme Opsin und Rhodopsin mittels zeitaufgelöster FTIR-Fluoreszenz-Kreuzkorrelations-Hydratations-Modulation untersucht. Diese Technik wurde eigens zur Aufklärung von zeitabhängigen Hydratationseffekten auf Lipide und Proteine oder Peptide entwickelt. Dabei werden zeitaufgelöste FTIR Differenz-Spektren und gleichzeitig statische Fluoreszenzsignale aufgenommen und diese zeitabhängigen multispektralen Datensätze mittels 2D Korrelation analysiert. Die Auswertung der Experimente enthüllt einen sequentiellen Hydratationsprozess. Dieser beginnt mit der Bildung von Wasserstoffbrückenbindungen an der Carbonylgruppe des Lipids, gefolgt von Strukturänderungen der Transmembranproteine und abgeschlossen durch das Eindringen von Wasser in das Proteininnere. Letzteres wird nachgewiesen durch die Fluoreszenz von Tryptophan im hydrophoben Peptid- oder Proteininneren. Die Ergebnisse dieser Arbeit unterstreichen die Annahme, dass Lipid-Protein-Wechselwirkungen eine entscheidende Rolle in der Funktion von Membranproteinen spielen und das insbesondere Elektrostatik, in Form von Ladungen an der Phasengrenze, und die Hydratisierung einen kritischen Einfluss auf diese Funktion haben

Distinct subpopulations of mechanosensory chordotonal organ neurons elicit grooming of the fruit fly antennae.

Diverse mechanosensory neurons detect different mechanical forces that can impact animal behavior. Yet our understanding of the anatomical and physiological diversity of these neurons and the behaviors that they influence is limited. We previously discovered that grooming of the Drosophila melanogaster antennae is elicited by an antennal mechanosensory chordotonal organ, the Johnston's organ (JO) (Hampel et al., 2015). Here, we describe anatomically and physiologically distinct JO mechanosensory neuron subpopulations that each elicit antennal grooming. We show that the subpopulations project to different, discrete zones in the brain and differ in their responses to mechanical stimulation of the antennae. Although activation of each subpopulation elicits antennal grooming, distinct subpopulations also elicit the additional behaviors of wing flapping or backward locomotion. Our results provide a comprehensive description of the diversity of mechanosensory neurons in the JO, and reveal that distinct JO subpopulations can elicit both common and distinct behavioral responses

Adult-Onset Leukoencephalopathy With Axonal Spheroids and Pigmented Glia: Review of Clinical Manifestations as Foundations for Therapeutic Development

A comprehensive review of published literature was conducted to elucidate the genetics, neuropathology, imaging findings, prevalence, clinical course, diagnosis/clinical evaluation, potential biomarkers, and current and proposed treatments for adult-onset leukoencephalopathy with axonal spheroids and pigmented glia (ALSP), a rare, debilitating, and life-threatening neurodegenerative disorder for which disease-modifying therapies are not currently available. Details on potential efficacy endpoints for future interventional clinical trials in patients with ALSP and data related to the burden of the disease on patients and caregivers were also reviewed. The information in this position paper lays a foundation to establish an effective clinical rationale and address the clinical gaps for creation of a robust strategy to develop therapeutic agents for ALSP, as well as design future clinical trials, that have clinically meaningful and convergent endpoints

The Molecular Switching Mechanism at the Conserved D(E)RY Motif in Class-A GPCRs

The disruption of ionic and H-bond interactions between the cytosolic ends of transmembrane helices TM3 and TM6 of class-A (rhodopsin-like) G protein-coupled receptors (GPCRs) is a hallmark for their activation by chemical or physical stimuli. In the bovine photoreceptor rhodopsin, this is accompanied by proton uptake at Glu134 in the class-conserved D(E)RY motif. Studies on TM3 model peptides proposed a crucial role of the lipid bilayer in linking protonation to stabilization of an active state-like conformation. However, the molecular details of this linkage could not be resolved and have been addressed in this study by molecular dynamics (MD) simulations on TM3 model peptides in a bilayer of 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC). We show that protonation of the conserved glutamic acid alters the peptide insertion depth in the membrane, its side-chain rotamer preferences, and stabilizes the C-terminal helical structure. These factors contribute to the rise of the side-chain pKa (> 6) and to reduced polarity around the TM3 C terminus as confirmed by fluorescence spectroscopy. Helix stabilization requires the protonated carboxyl group; unexpectedly, this stabilization could not be evoked with an amide in MD simulations. Additionally, time-resolved Fourier transform infrared (FTIR) spectroscopy of TM3 model peptides revealed a different kinetics for lipid ester carbonyl hydration, suggesting that the carboxyl is linked to more extended H-bond clusters than an amide. Remarkably, this was seen as well in DOPC-reconstituted Glu134- and Gln134-containing bovine opsin mutants and demonstrates that the D(E)RY motif is a hydrated microdomain. The function of the D(E)RY motif as a proton switch is suggested to be based on the reorganization of the H-bond network at the membrane interface

3D Profile-Based Approach to Proteome-Wide Discovery of Novel Human Chemokines

Chemokines are small secreted proteins with important roles in immune responses. They consist of a conserved three-dimensional (3D) structure, so-called IL8-like chemokine fold, which is supported by disulfide bridges characteristic of this protein family. Sequence- and profile-based computational methods have been proficient in discovering novel chemokines by making use of their sequence-conserved cysteine patterns. However, it has been recently shown that some chemokines escaped annotation by these methods due to low sequence similarity to known chemokines and to different arrangement of cysteines in sequence and in 3D. Innovative methods overcoming the limitations of current techniques may allow the discovery of new remote homologs in the still functionally uncharacterized fraction of the human genome. We report a novel computational approach for proteome-wide identification of remote homologs of the chemokine family that uses fold recognition techniques in combination with a scaffold-based automatic mapping of disulfide bonds to define a 3D profile of the chemokine protein family. By applying our methodology to all currently uncharacterized human protein sequences, we have discovered two novel proteins that, without having significant sequence similarity to known chemokines or characteristic cysteine patterns, show strong structural resemblance to known anti-HIV chemokines. Detailed computational analysis and experimental structural investigations based on mass spectrometry and circular dichroism support our structural predictions and highlight several other chemokine-like features. The results obtained support their functional annotation as putative novel chemokines and encourage further experimental characterization. The identification of remote homologs of human chemokines may provide new insights into the molecular mechanisms causing pathologies such as cancer or AIDS, and may contribute to the development of novel treatments. Besides, the genome-wide applicability of our methodology based on 3D protein family profiles may open up new possibilities for improving and accelerating protein function annotation processes

The ARID1B spectrum in 143 patients: from nonsyndromic intellectual disability to Coffin–Siris syndrome

Purpose: Pathogenic variants in ARID1B are one of the most frequent causes of intellectual disability (ID) as determined by large-scale exome sequencing studies. Most studies published thus far describe clinically diagnosed Coffin–Siris patients (ARID1B-CSS) and it is unclear whether these data are representative for patients identified through sequencing of unbiased ID cohorts (ARID1B-ID). We therefore sought to determine genotypic and phenotypic differences between ARID1B-ID and ARID1B-CSS. In parallel, we investigated the effect of different methods of phenotype reporting. Methods: Clinicians entered clinical data in an extensive web-based survey. Results: 79 ARID1B-CSS and 64 ARID1B-ID patients were included. CSS-associated dysmorphic features, such as thick eyebrows, long eyelashes, thick alae nasi, long and/or broad philtrum, small nails and small or absent fifth distal phalanx and hypertrichosis, were observed significantly more often (p < 0.001) in ARID1B-CSS patients. No other significant differences were identified. Conclusion: There are only minor differences between ARID1B-ID and ARID1B-CSS patients. ARID1B-related disorders seem to consist of a spectrum, and patients should be managed similarly. We demonstrated that data collection methods without an explicit option to report the absence of a feature (such as most Human Phenotype Ontology-based methods) tended to underestimate gene-related features

Structure, Function and Dynamics of G-Protein coupled Receptors

Understanding the function of membrane proteins is crucial to elucidate the molecular mechanisms by which transmembrane signaling based physiological processes,i. e., the interactions of extracellular ligands with membrane-bound receptors, are regulated. In this work, synthetic transmembrane segments derived from the visual photoreceptor rhodopsin, the full length system rhodopsin and mutants of opsin are used to study physical processes that underlie the function of this prototypical class-A G-protein coupled Receptor. The dependency of membrane protein hydration and protein-lipid interactions on side chain charge neutralization is addressed by fluorescence spectroscopy on synthetic transmembrane segments in detergent and lipidic environment constituting transmembrane segments of rhodopsin in the membrane. Results from spectroscopic studies allow us to construct a structural and thermodynamical model of coupled protonation of the conserved ERY motif in transmembrane helix 3 of rhodopsin and of helix restructuring in the micro-domain formed at the protein/lipid water phase boundary. Furthermore, synthesized peptides and full length systems were studied by time resolved FTIR-Fluorescence Cross Correlation Hydration Modulation, a technique specifically developed for the purpose of this study, to achieve a full prospect of time-resolved hydration effects on lipidic and proteinogenic groups, as well as their interactions. Multi-spectral experiments and time-dependent analyses based on 2D correlation where established to analyze large data sets obtained from time-resolved FTIR difference spectra and simultaneous static fluorescence recordings. The data reveal that lipids play a mediating role in transmitting hydration to the subsequent membrane protein response followed by water penetration into the receptor structure or into the sub-headgroup region in single membrane-spanning peptides carrying the conserved proton uptake site (monitored by the fluorescence emission of hydrophobic buried tryptophan). Our results support the assumption of the critical role of the lipid/water interface in membrane protein function and they prove in particular the important influence of electrostatics, i. e., side chain charges at the phase boundary, and hydration on that function.Für die Aufklärung der molekularen Wirkungsweise von physiologischen, auf Signaltransduktion, d. h. dem Zusammenspiel von extrazellulären Reizen und membrangebundenen Rezeptoren, beruhenden Prozessen ist das Verständnis der Funktion von Membranproteinen unerlässlich. In dieser Arbeit werden von Rhodopsin abgleitete, synthetische transmembrane Segmentpeptide, Opsin-Mutanten und der vollständige Photorezeptor Rhodopsin untersucht, um die physikalischen Prozesse zu beleuchten, die der Funktionen dieses prototypischen Klasse-A G-Protein gekoppelten Rezeptors zugrunde liegen. Die Abhängigkeit der Membranprotein-Hydratation und der Lipid-Protein-Wechselwirkung von der Ladung einer Aminosäuren-Seitenkette wird erforscht. Hierzu werden synthetische, transmembrane Segmentpeptide in Lipid und Detergenz, als Modell transmembraner Segmente von Rhodopsin in der Membran mittels Fluoreszenzspektroskopie untersucht. Aus den erhaltenen Ergebnissen wird ein thermodynamisches und strukturelles Modell hergeleitet, welches die Kopplung der Protonierung des hochkonservierten ERY-Motivs in Transmembranhelix 3 von Rhodopsin an die Restrukturierung der Helix in der Mikroumgebung der Lipid-Wasser-Phasengrenze erklärt. Des Weiteren werden sowohl die Segementpeptide als auch die vollständigen Systeme Opsin und Rhodopsin mittels zeitaufgelöster FTIR-Fluoreszenz-Kreuzkorrelations-Hydratations-Modulation untersucht. Diese Technik wurde eigens zur Aufklärung von zeitabhängigen Hydratationseffekten auf Lipide und Proteine oder Peptide entwickelt. Dabei werden zeitaufgelöste FTIR Differenz-Spektren und gleichzeitig statische Fluoreszenzsignale aufgenommen und diese zeitabhängigen multispektralen Datensätze mittels 2D Korrelation analysiert. Die Auswertung der Experimente enthüllt einen sequentiellen Hydratationsprozess. Dieser beginnt mit der Bildung von Wasserstoffbrückenbindungen an der Carbonylgruppe des Lipids, gefolgt von Strukturänderungen der Transmembranproteine und abgeschlossen durch das Eindringen von Wasser in das Proteininnere. Letzteres wird nachgewiesen durch die Fluoreszenz von Tryptophan im hydrophoben Peptid- oder Proteininneren. Die Ergebnisse dieser Arbeit unterstreichen die Annahme, dass Lipid-Protein-Wechselwirkungen eine entscheidende Rolle in der Funktion von Membranproteinen spielen und das insbesondere Elektrostatik, in Form von Ladungen an der Phasengrenze, und die Hydratisierung einen kritischen Einfluss auf diese Funktion haben

Mixed Cropping as Affected by Phosphorus and Water Supply

In a future exposed to threats of climate change, sustainable biomass production will be crucial. Maize (Zea mays) and sorghum (Sorghum sp.) are important crops for human and animal nutrition, as well as for bioenergy. The aim of this study was to investigate maize and sorghum in mixed cropping with soybean (Glycine max) and faba bean (Vicia faba) regarding biomass yield, drought tolerance, phosphorus (P) availability, and enzyme activity in soil as affected by the single and combined effects of water and P supply in two outdoor pot trials with rainout shelters. Maize had the highest biomass under sufficient water supply (80% water holding capacity, WHC), but a sharp decrease of its biomass of about 60% was measured when water was limited (30% WHC). In the mixtures, drought induced reduction of biomass was less than 40%. For mixed cropping usually higher contents of labile P fractions in soil than for sole cropped monocots were found. This was especially true for the combined stress of water and P deficit and can be partly explained by a higher activity of the acid phosphatase in the soil of the mixtures. A higher yield stability of the crop mixtures makes them a suitable agronomic alternative to sole cropped maize or sorghum under suboptimal conditions of water and P shortage